Understanding forward particle production

Understanding forward particle production

Opportunities for Drell-Yan Physics at RHIC May 13th, 2011

Roman Pasechnik

Uppsala University, THEP group

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In collaboration withB. Kopeliovich (USM, Chile)

We will talk about...

Color neutralization and soft physics in diffractive DIS

Sudakov suppression and elastic scattering

Drell-Yan at high energies: diffractive vs inclusive

Large and small dipoles

Eikonalization of the elastic amplitude and gap survival

Summary

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time

Perturbative color neutralizationSoft/semihard color neutralization

Lack of absorptive effects!

Both include unitarity corrections and color neutralisation

Both diffractive – nondiffractiveprocesses

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Color screening effects in different asymptotics

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Color screening in diffractive DIS

Hard partconventional

(small distance) Soft part: color-screening (octet) multigluon exchange

(large distance)

Diffractive DIS at HERA QCD rescattering model

Pasechnik, Enberg, Ingelman, Phys.Rev. D82 (2010) 054036

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Sudakov suppression and elastic scattering

Color neutralization is automatic,no radiation into the gap,

small MX is produced, no need in Sudakov!

Color neutralization is required for diffraction

Hard gluon Bremsstrahlung contributes at larger MX

soft gluons – a part of UGDF!

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For diffractive small MX productionSudakov suppression is needed!

Photon radiation in the forward quark scattering

…in inelastic collision

…in elastic collision

Radiation depends on the whole strength of the kick rather on its structure No radiation from a quark at Pt=0!

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Diffractive Drell-Yan in the dipole-target scattering

By optical theorem

Amplitude of DDY in the dipole-target scattering

dipoles with different sizes interact differently!

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Diffractive Drell-Yan in pp scattering: amplitude

B. Kopeliovich, I. Potashnikova, I. Schmidt and A. Tarasov, Phys. Rev. D74, (2006) 114024

Diffractive DY amplitude ..probing large distances in the proton

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QCD factorization breaking in diffractive Drell-Yan

Diffractive DY amplitude

Golec-Biernat-Wuestoff (GBW) dipole cross section

Interplay between hard and soft scales

Difference between two Fock states

Diffractive DIS Diffractive DY

Dramatic breakdown of the QCD factorization!The QCD factorization holds!

Small and large dipoles

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Golec-Biernat-Wuestoff (GBW) parameterization

Kopeliovich- Schafer -Tarasov (KST) parameterization

Fitted to DIS data Fitted to soft data

DDY!

Phys. Rev. D 62 (2000) , 054022

Eikonalization of the diffractive Drell-Yan amplitude

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Accounts for soft and hard components on the same footing!

DDY eikonalized amplitude

Diffractive Drell-Yan in pp scattering: cross section

In the forward limit

Proton wave function

Valence quark distribution + antiquarks!

Gap survival vs. eikonalization

Regge parameterization for F2Cudell, Soyez, Phys.Lett. B516 (2001), 77

Gap survival vs. eikonalization

Diffractive vs. inclusive DY

Diffractive vs. inclusive DY

Theory uncertainties

Conclusions

A quark cannot radiate photon diffractively in the forward direction

A hadron can radiate photon diffractively in the forward direction because of the transverse motion of quarks

The ratio diffractive/inclusive DY cross sections falls with energy and rises with photon dilepton mass due to the saturated shape of the dipole cross section

Hard and soft interactions contribute to the DDY on the same footing, which is the dramatic breakdown of the QCD factorisation

Main features of Drell-Yan diffraction are valid for other Abelian processes

Experimental measurements of DDY would allow to probe directly the dipole cross section at large separations, as well as the proton structure function at soft and semihard scales, and large x

DDY is a good playground for diffractive production of heavy flavors